DE3426067A1 - Circuit arrangement for correcting phase errors of the horizontal deflection in a television set - Google Patents

Abstract

In television sets in which the extra high tension is generated in the horizontal deflection stage, reactions of the beam current on the horizontal deflection, which become noticeable as phase errors by displaying a distorted image, occur particularly with a high beam current and low picture tube capacitance. To reduce the phase error, it is known to supply a phase comparison circuit with a reference pulse from the deflection transformer in order to generate a control voltage counteracting the phase error. However, a residual error still remains. This residual error is eliminated by the invention in that a beam-current-dependent correction voltage is superimposed on the control voltage, which can be picked up either at the bottom end of the extra high tension source or across the bias resistor of the operating voltage source for the horizontal deflection stage.

Description

Circuit arrangement for the correction of

Phasing errors of horizontal deflection in a television set The invention relates to a circuit arrangement for correcting phase position errors the horizontal deflection in a television set, with a first and a second Phase comparison circuit comprising preferably integrated circuit, wherein the second phase comparison circuit generates a control voltage, as well as with a Horizontal output stage, of which the high voltage is generated in a high voltage winding Deflection transformer via an auxiliary winding a reference voltage to the second phase comparison circuit especially for teletext devices and monitors.

In the case of televisions, the required for the operation of the picture tube High voltage usually obtained in the horizontal output stage. This spread The type of high voltage generation, however, results in large and small beam currents Picture tube capacities for the effects of the beam current on the horizontal deflection.

These repercussions can be explained, among other things, by the fact that with a large jet stream at the high one Internal resistance of the operating voltage source a noticeable voltage drop occurs, which leads to fluctuations in the high voltage leads.

The influence of the picture tube capacitance is noticeable only with small capacitance values to be observed, because with a large capacity the current is kept relatively constant, so that then hardly any repercussions on the high voltage can be observed.

As a result of the mentioned repercussions of the jet stream on the horizontal deflection As is known, image width and phase position errors occur. The screen width errors can easily be adjusted in an east-west pillow equalization if necessary, namely in the sense of a beam current-dependent image width correction. The focus is therefore directed in the following to the phase position errors, their elimination so far encountered problems.

If there is a phase position error - that is, if the phase position between the video signal and the deflection current deviates from the correct position - correct the optical center of the image does not match the electrical one related to the video signal Center of image. The viewer takes the Phasing errors therefore as a one-sided or asymmetrical shift related to the center of the image or Distortion of the reproduced image is true.

With the circuit arrangement of the type mentioned is already phase angle errors can be compensated for by using the second phase comparison circuit is applied with a reference pulse or a reference voltage, which over an auxiliary winding of the deflection transformer is generated. The second phase comparison circuit supplies a control voltage which is fed to one of the horizontal oscillator Pulse shaper is guided to the beginning - i.e. the phase position - of the horizontal output stage the controlling horizontal pulse depending on the control voltage.

In practice, however, the known circuit arrangement mentioned has proven itself can only partially prove, because a complete elimination of the phase position errors is not possible with the solution described. The second phase comparison circuit reacts due to the supplied reference pulse on phase changes, however, can it is found that the phase position change determined on the basis of the reference pulse not is identical to the phase change, which causes the previously mentioned one-sided shift of the image content. This fact is probably due to scatter and phase errors within the horizontal output stage with the deflection transformer, and the rest of the second phase comparison circuit takes effect only then fully in the sense of a correction, if the reference impulses change symmetrically.

The residual error that remains in the known circuit arrangement is negligible for most screen contents and by the viewer barely noticeable, but this does not apply to teletext devices or for monitors, where diagrams or graphic figures are often displayed, where the symmetry (in relation to the center of the picture) is particularly important. Here is also the residual error perceptible to the viewer by the graphic figures appear distorted on one side.

The remaining residual error increases particularly with large jet flows and small picture tube capacities too.

However, these two features are often present, because one is graphical Require on-screen display the light lines high Beam streams, and besides, the often used small picture tubes also have a relatively small capacity. Therefore there is a special need here also to eliminate the residual error.

The invention is therefore based on the object of a circuit arrangement to create, which enables a further correction of phase position errors, so that the picture content flows even with a large beam and small picture tube capacities remains undistorted.

This problem is solved in the preamble of the claim 1 required circuit arrangement in that the control voltage of the second Phase comparison circuit superimposed a beam current-dependent correction voltage is.

The invention is based on the idea of the regulation known to me with the reference pulse and the control voltage generated in this way an additional Superimpose voltage as correction voltage. In the actual generation of the control voltage itself is therefore not intervened, rather the with the help of the reference pulse generated control voltage additionally superimposed with a correction voltage, the size of which depends on the strength of the respective jet stream. Surprised Tests have shown that with this simple measure, the above Remaining errors described can largely be eliminated, so that even with a large beam stream and undistorted picture reproduction is possible with small picture tube capacities is.

The invention makes do with simple and inexpensive means. It is sufficient to connect the control voltage output of the second phase comparison stage with a To connect the circuit point of the horizontal output stage, at which one the beam current proportional voltage is available. Such a switching point lies on the high-voltage winding of the deflection transformer, this node being according to an advantageous embodiment of the invention via the series connection of a Capacitor and a resistor - these are only those required in the invention additional components - with the control voltage output of the second phase comparison circuit is connected.

According to another advantageous development of the invention takes place the tap of the voltage proportional to the beam current at that end of the Primary winding of the deflection transformer, which has a series resistor is connected to the operating voltage source for the horizontal output stage.

The solution according to the invention obviously only requires a small one Circuit effort, because only two components are required, which the Elimination of the phase error made possible by the retroactive effect of the beam current on the image geometry.

Further advantageous refinements of the invention are set out in the subclaims and to be taken from the drawing.

The invention is illustrated below with reference to what is shown in the drawing Embodiment explained in more detail, which is a basic circuit diagram of a circuit arrangement shows for correcting phase position errors, with two possible variants of the invention are shown.

The circuit arrangement comprises as part of the overall circuit one television set, not shown in detail, an integrated circuit 20, which is here by the type TDA 2595 is formed. The designation of the external connections 2, 3, 4 and 11 corresponds to the pin assignment of the integrated circuit 20 as shown in FIG the application is specified.

The composite signal reaches a pulse separator via connection 11 2?, The output of which is connected to a first phase comparison circuit 24. the integrated circuit 20 further includes a horizontal oscillator 26, the first Phase comparison circuit 24 and the second phase comparison circuit 30 with horizontal pulses as a reference signal and also a pulse shaper 28 also horizontal pulses feeds.

In the first phase comparison circuit 24, the horizontal pulse compared by the horizontal oscillator 26 with the synchronous component of the composite signal, while in the second phase comparison circuit 30, a comparison of the horizontal pulse takes place with a reference pulse, which by means of an auxiliary winding 66 of the deflection transformer 46 and the second phase comparison circuit 30th is supplied via connection 2.

The control voltage obtained by the second phase comparison circuit 30, which is available at pin 3, reaches the pulse shaper 28 to begin there or to determine the phase position of the horizontal pulses. Pin 3 is over a Filter capacitor 32 connected to ground in order to achieve a smoothing of the control voltage.

The fixed in its phase position by means of the pulse shaper 28 Horizontal pulse reaches a switching transistor via a horizontal driver stage 34 36, which is part of the horizontal output stage. The emitter of the switching transistor 36 is connected to ground, and the collector leads through a tangent capacitor 38 and a linearity controller 40 to the horizontal deflection coil 42. In the collector circuit of the switching transistor 36 is a diode modulator 44 for the east-west pincushion equalization in a known manner. In addition, the deflection transformer 46 is connected to the collector of the switching transistor 36 connected, the primary winding 70 of which via a series resistor 68 to an operating voltage source u is connected.

B on the high voltage winding 48 of the deflection transformer 46 with the help of a rectifier 50 the high voltage UH won, which by a consisting of a resistor 54 and a capacitor 56 filter element is smoothed. The arrow 58 provides a connection to the jet current limiting circuit known per se indicated.

The collector of the switching transistor 36 is via an inductance 60 still with a power transistor 62 for a conventional east-west control circuit 64 connected, and via a control circuit 80 there is another beam-current-dependent Image width correction.

The circuit arrangement described so far is known.

To better illustrate the invention, the associated circuit parts are Particularly highlighted in the drawing by thick lines and by a dashed line Drawn switch 78 are indicated two possible embodiments of the invention.

In one embodiment, there is a tap point 52 at the lower end the high-voltage winding 48 via a capacitor 74 and a resistor 76 the control voltage output 3 of the second phase comparison circuit 30 is connected. A voltage corresponding to the beam current intensity is available at the tap point 52 This is available as a correction voltage for the control voltage output 3 arrives and there the control voltage is superimposed. The capacitor 44 takes over the function of a coupling capacitor to the DC voltage from the control voltage output 3 keep away. Only the voltage changes that occur become the control voltage superimposed as a correction voltage.

The correction voltage fed to the control voltage output 3 can alternatively also taken from the tapping point 72 as a jet-current-dependent voltage will.

This solution is particularly advantageous because the beam current-dependent one Voltage at tap point 72 between series resistor 68 and the primary winding 70 is normally less integrated, i.e. more smoothed and therefore right corresponds exactly to the beam current.

The dimensioning of the resistor 76 depends on the size at the respective tapping points 52 at the base of the high voltage source or beam current-dependent available at the tap point 72 on the series resistor 68 Voltages and according to the control sensitivity of the second phase comparison circuit 30. In a practical embodiment, a value of 200 KOhm selected.

If the resistor 76 is dimensioned correctly, phase position errors can be observed even with a high peak beam flow out, so that there is no on the screen Distortions occur more. If necessary - depending on the "control direction" within of the integrated circuit 20 - one more transistor stage is required for phase rotation, this transistor stage then between the resistor 76 and the control voltage output 3 can be inserted.

The invention is not limited to the two tapping points 52 and 72; The only thing that matters is to choose such a tap point at which the actual Beam current can be measured to the control voltage with a beam current dependent To superimpose correction voltage, the resulting control voltage then Residual errors largely eliminated.

Claims (4)

Circuit arrangement for correcting phase position errors the horizontal deflection in a television set, with a first and a second Phase comparison circuit comprising preferably integrated circuit, wherein the second phase comparison circuit generates a control voltage, as well as with a Horizontal output stage, of which the high voltage is generated in a high voltage winding Deflection transformer via an auxiliary winding a reference voltage to the second phase comparison circuit is performed, in particular for teletext devices and monitors, characterized in that that the control voltage of the second phase comparison circuit (30) is a beam current-dependent Correction voltage is superimposed. 2. Circuit arrangement according to claim 1, characterized in that the correction voltage on the high voltage winding (48) of the deflection transformer is tapped (52). 3. Circuit arrangement according to claim 1, characterized in that the correction voltage at the via a series resistor (68) with the operating voltage source (U) for the horizontal output stage connected B end (72) of the primary winding (70) of the deflection transformer (46) is tapped. 4. Circuit arrangement according to one of the preceding claims 1 - 3, characterized in that the beam current-dependent correction voltage via a Series connection of a capacitor (74) and a resistor (76) to the control voltage output (3) the second phase comparison circuit (30) is performed.